/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* vim:set ts=4 sw=4 sts=4 et: */ /* * Copyright (c) 2012, 2013 The Linux Foundation. All rights reserved. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include "gfxPrefs.h" #include "ImageLayers.h" #include "libdisplay/GonkDisplay.h" #include "HwcComposer2D.h" #include "LayerScope.h" #include "Units.h" #include "mozilla/ClearOnShutdown.h" #include "mozilla/layers/CompositorParent.h" #include "mozilla/layers/LayerManagerComposite.h" #include "mozilla/layers/PLayerTransaction.h" #include "mozilla/layers/ShadowLayerUtilsGralloc.h" #include "mozilla/layers/TextureHostOGL.h" // for TextureHostOGL #include "mozilla/StaticPtr.h" #include "nsThreadUtils.h" #include "cutils/properties.h" #include "gfx2DGlue.h" #include "gfxPlatform.h" #include "VsyncSource.h" #include "nsScreenManagerGonk.h" #include "nsWindow.h" #if ANDROID_VERSION >= 17 #include "libdisplay/DisplaySurface.h" #endif #ifdef LOG_TAG #undef LOG_TAG #endif #define LOG_TAG "HWComposer" /* * By default the debug message of hwcomposer (LOG_DEBUG level) are undefined, * but can be enabled by uncommenting HWC_DEBUG below. */ //#define HWC_DEBUG #ifdef HWC_DEBUG #define LOGD(args...) __android_log_print(ANDROID_LOG_DEBUG, LOG_TAG, ## args) #else #define LOGD(args...) ((void)0) #endif #define LOGI(args...) __android_log_print(ANDROID_LOG_INFO, LOG_TAG, ## args) #define LOGE(args...) __android_log_print(ANDROID_LOG_ERROR, LOG_TAG, ## args) #define LAYER_COUNT_INCREMENTS 5 using namespace android; using namespace mozilla::gfx; using namespace mozilla::layers; namespace mozilla { static void HookInvalidate(const struct hwc_procs* aProcs) { HwcComposer2D::GetInstance()->Invalidate(); } static void HookVsync(const struct hwc_procs* aProcs, int aDisplay, int64_t aTimestamp) { HwcComposer2D::GetInstance()->Vsync(aDisplay, aTimestamp); } static void HookHotplug(const struct hwc_procs* aProcs, int aDisplay, int aConnected) { HwcComposer2D::GetInstance()->Hotplug(aDisplay, aConnected); } static StaticRefPtr sInstance; HwcComposer2D::HwcComposer2D() : mList(nullptr) , mMaxLayerCount(0) , mColorFill(false) , mRBSwapSupport(false) , mPrepared(false) , mHasHWVsync(false) , mLock("mozilla.HwcComposer2D.mLock") { mHal = HwcHALBase::CreateHwcHAL(); if (!mHal->HasHwc()) { LOGD("no hwc support"); return; } RegisterHwcEventCallback(); nsIntSize screenSize; GonkDisplay::NativeData data = GetGonkDisplay()->GetNativeData(GonkDisplay::DISPLAY_PRIMARY); ANativeWindow *win = data.mNativeWindow.get(); win->query(win, NATIVE_WINDOW_WIDTH, &screenSize.width); win->query(win, NATIVE_WINDOW_HEIGHT, &screenSize.height); mScreenRect = gfx::IntRect(gfx::IntPoint(0, 0), screenSize); mColorFill = mHal->Query(HwcHALBase::QueryType::COLOR_FILL); mRBSwapSupport = mHal->Query(HwcHALBase::QueryType::RB_SWAP); } HwcComposer2D::~HwcComposer2D() { free(mList); } HwcComposer2D* HwcComposer2D::GetInstance() { if (!sInstance) { #ifdef HWC_DEBUG // Make sure only create once static int timesCreated = 0; ++timesCreated; MOZ_ASSERT(timesCreated == 1); #endif LOGI("Creating new instance"); sInstance = new HwcComposer2D(); // If anyone uses the compositor thread to create HwcComposer2D, // we just skip this function. // If ClearOnShutdown() can handle objects in other threads // in the future, we can remove this check. if (NS_IsMainThread()) { // If we create HwcComposer2D by the main thread, we can use // ClearOnShutdown() to make sure it will be nullified properly. ClearOnShutdown(&sInstance); } } return sInstance; } bool HwcComposer2D::EnableVsync(bool aEnable) { MOZ_ASSERT(NS_IsMainThread()); if (!mHasHWVsync) { return false; } return mHal->EnableVsync(aEnable) && aEnable; } bool HwcComposer2D::RegisterHwcEventCallback() { const HwcHALProcs_t cHWCProcs = { &HookInvalidate, // 1st: void (*invalidate)(...) &HookVsync, // 2nd: void (*vsync)(...) &HookHotplug // 3rd: void (*hotplug)(...) }; mHasHWVsync = mHal->RegisterHwcEventCallback(cHWCProcs); return mHasHWVsync; } void HwcComposer2D::Vsync(int aDisplay, nsecs_t aVsyncTimestamp) { // Only support hardware vsync on kitkat, L and up due to inaccurate timings // with JellyBean. #if (ANDROID_VERSION == 19 || ANDROID_VERSION >= 21) TimeStamp vsyncTime = mozilla::TimeStamp::FromSystemTime(aVsyncTimestamp); gfxPlatform::GetPlatform()->GetHardwareVsync()->GetGlobalDisplay().NotifyVsync(vsyncTime); #else // If this device doesn't support vsync, this function should not be used. MOZ_ASSERT(false); #endif } // Called on the "invalidator" thread (run from HAL). void HwcComposer2D::Invalidate() { if (!mHal->HasHwc()) { LOGE("HwcComposer2D::Invalidate failed!"); return; } MutexAutoLock lock(mLock); if (mCompositorParent) { mCompositorParent->ScheduleRenderOnCompositorThread(); } } namespace { class HotplugEvent : public nsRunnable { public: HotplugEvent(GonkDisplay::DisplayType aType, bool aConnected) : mType(aType) , mConnected(aConnected) { } NS_IMETHOD Run() { RefPtr screenManager = nsScreenManagerGonk::GetInstance(); if (mConnected) { screenManager->AddScreen(mType); } else { screenManager->RemoveScreen(mType); } return NS_OK; } private: GonkDisplay::DisplayType mType; bool mConnected; }; } // namespace void HwcComposer2D::Hotplug(int aDisplay, int aConnected) { NS_DispatchToMainThread(new HotplugEvent(GonkDisplay::DISPLAY_EXTERNAL, aConnected)); } void HwcComposer2D::SetCompositorParent(CompositorParent* aCompositorParent) { MutexAutoLock lock(mLock); mCompositorParent = aCompositorParent; } bool HwcComposer2D::ReallocLayerList() { int size = sizeof(HwcList) + ((mMaxLayerCount + LAYER_COUNT_INCREMENTS) * sizeof(HwcLayer)); HwcList* listrealloc = (HwcList*)realloc(mList, size); if (!listrealloc) { return false; } if (!mList) { //first alloc, initialize listrealloc->numHwLayers = 0; listrealloc->flags = 0; } mList = listrealloc; mMaxLayerCount += LAYER_COUNT_INCREMENTS; return true; } bool HwcComposer2D::PrepareLayerList(Layer* aLayer, const nsIntRect& aClip, const Matrix& aParentTransform) { // NB: we fall off this path whenever there are container layers // that require intermediate surfaces. That means all the // GetEffective*() coordinates are relative to the framebuffer. bool fillColor = false; const nsIntRegion visibleRegion = aLayer->GetEffectiveVisibleRegion().ToUnknownRegion(); if (visibleRegion.IsEmpty()) { return true; } uint8_t opacity = std::min(0xFF, (int)(aLayer->GetEffectiveOpacity() * 256.0)); if (opacity == 0) { LOGD("%s Layer has zero opacity; skipping", aLayer->Name()); return true; } if (!mHal->SupportTransparency() && opacity < 0xFF) { LOGD("%s Layer has planar semitransparency which is unsupported by hwcomposer", aLayer->Name()); return false; } if (aLayer->GetMaskLayer()) { LOGD("%s Layer has MaskLayer which is unsupported by hwcomposer", aLayer->Name()); return false; } nsIntRect clip; nsIntRect layerClip = aLayer->GetEffectiveClipRect().valueOr(ParentLayerIntRect()).ToUnknownRect(); nsIntRect* layerClipPtr = aLayer->GetEffectiveClipRect() ? &layerClip : nullptr; if (!HwcUtils::CalculateClipRect(aParentTransform, layerClipPtr, aClip, &clip)) { LOGD("%s Clip rect is empty. Skip layer", aLayer->Name()); return true; } // HWC supports only the following 2D transformations: // // Scaling via the sourceCrop and displayFrame in HwcLayer // Translation via the sourceCrop and displayFrame in HwcLayer // Rotation (in square angles only) via the HWC_TRANSFORM_ROT_* flags // Reflection (horizontal and vertical) via the HWC_TRANSFORM_FLIP_* flags // // A 2D transform with PreservesAxisAlignedRectangles() has all the attributes // above Matrix layerTransform; if (!aLayer->GetEffectiveTransform().Is2D(&layerTransform) || !layerTransform.PreservesAxisAlignedRectangles()) { LOGD("Layer EffectiveTransform has a 3D transform or a non-square angle rotation"); return false; } Matrix layerBufferTransform; if (!aLayer->GetEffectiveTransformForBuffer().Is2D(&layerBufferTransform) || !layerBufferTransform.PreservesAxisAlignedRectangles()) { LOGD("Layer EffectiveTransformForBuffer has a 3D transform or a non-square angle rotation"); return false; } if (ContainerLayer* container = aLayer->AsContainerLayer()) { if (container->UseIntermediateSurface()) { LOGD("Container layer needs intermediate surface"); return false; } nsAutoTArray children; container->SortChildrenBy3DZOrder(children); for (uint32_t i = 0; i < children.Length(); i++) { if (!PrepareLayerList(children[i], clip, layerTransform)) { return false; } } return true; } LayerRenderState state = aLayer->GetRenderState(); #if ANDROID_VERSION >= 21 if (!state.GetGrallocBuffer() && !state.GetSidebandStream()) { #else if (!state.GetGrallocBuffer()) { #endif if (aLayer->AsColorLayer() && mColorFill) { fillColor = true; } else { LOGD("%s Layer doesn't have a gralloc buffer", aLayer->Name()); return false; } } nsIntRect visibleRect = visibleRegion.GetBounds(); nsIntRect bufferRect; if (fillColor) { bufferRect = nsIntRect(visibleRect); } else { nsIntRect layerRect; if (state.mHasOwnOffset) { bufferRect = nsIntRect(state.mOffset.x, state.mOffset.y, state.mSize.width, state.mSize.height); layerRect = bufferRect; } else { //Since the buffer doesn't have its own offset, assign the whole //surface size as its buffer bounds bufferRect = nsIntRect(0, 0, state.mSize.width, state.mSize.height); layerRect = bufferRect; if (aLayer->GetType() == Layer::TYPE_IMAGE) { ImageLayer* imageLayer = static_cast(aLayer); if(imageLayer->GetScaleMode() != ScaleMode::SCALE_NONE) { layerRect = nsIntRect(0, 0, imageLayer->GetScaleToSize().width, imageLayer->GetScaleToSize().height); } } } // In some cases the visible rect assigned to the layer can be larger // than the layer's surface, e.g., an ImageLayer with a small Image // in it. visibleRect.IntersectRect(visibleRect, layerRect); } // Buffer rotation is not to be confused with the angled rotation done by a transform matrix // It's a fancy PaintedLayer feature used for scrolling if (state.BufferRotated()) { LOGD("%s Layer has a rotated buffer", aLayer->Name()); return false; } const bool needsYFlip = state.OriginBottomLeft() ? true : false; hwc_rect_t sourceCrop, displayFrame; if(!HwcUtils::PrepareLayerRects(visibleRect, layerTransform, layerBufferTransform, clip, bufferRect, needsYFlip, &(sourceCrop), &(displayFrame))) { return true; } // OK! We can compose this layer with hwc. int current = mList ? mList->numHwLayers : 0; // Do not compose any layer below full-screen Opaque layer // Note: It can be generalized to non-fullscreen Opaque layers. bool isOpaque = opacity == 0xFF && (state.mFlags & LayerRenderStateFlags::OPAQUE); // Currently we perform opacity calculation using the *bounds* of the layer. // We can only make this assumption if we're not dealing with a complex visible region. bool isSimpleVisibleRegion = visibleRegion.Contains(visibleRect); if (current && isOpaque && isSimpleVisibleRegion) { nsIntRect displayRect = nsIntRect(displayFrame.left, displayFrame.top, displayFrame.right - displayFrame.left, displayFrame.bottom - displayFrame.top); if (displayRect.Contains(mScreenRect)) { // In z-order, all previous layers are below // the current layer. We can ignore them now. mList->numHwLayers = current = 0; mHwcLayerMap.Clear(); } } if (!mList || current >= mMaxLayerCount) { if (!ReallocLayerList() || current >= mMaxLayerCount) { LOGE("PrepareLayerList failed! Could not increase the maximum layer count"); return false; } } HwcLayer& hwcLayer = mList->hwLayers[current]; hwcLayer.displayFrame = displayFrame; mHal->SetCrop(hwcLayer, sourceCrop); buffer_handle_t handle = nullptr; #if ANDROID_VERSION >= 21 if (state.GetSidebandStream()) { handle = state.GetSidebandStream()->handle(); } else if (state.GetGrallocBuffer()) { handle = state.GetGrallocBuffer()->getNativeBuffer()->handle; } #else if (state.GetGrallocBuffer()) { handle = state.GetGrallocBuffer()->getNativeBuffer()->handle; } #endif hwcLayer.handle = handle; hwcLayer.flags = 0; hwcLayer.hints = 0; hwcLayer.blending = isOpaque ? HWC_BLENDING_NONE : HWC_BLENDING_PREMULT; #if ANDROID_VERSION >= 17 hwcLayer.compositionType = HWC_FRAMEBUFFER; #if ANDROID_VERSION >= 21 if (state.GetSidebandStream()) { hwcLayer.compositionType = HWC_SIDEBAND; } #endif hwcLayer.acquireFenceFd = -1; hwcLayer.releaseFenceFd = -1; #if ANDROID_VERSION >= 18 hwcLayer.planeAlpha = opacity; #endif #else hwcLayer.compositionType = HwcUtils::HWC_USE_COPYBIT; #endif if (!fillColor) { if (state.FormatRBSwapped()) { if (!mRBSwapSupport) { LOGD("No R/B swap support in H/W Composer"); return false; } hwcLayer.flags |= HwcUtils::HWC_FORMAT_RB_SWAP; } // Translation and scaling have been addressed in PrepareLayerRects(). // Given the above and that we checked for PreservesAxisAlignedRectangles() // the only possible transformations left to address are // square angle rotation and horizontal/vertical reflection. // // The rotation and reflection permutations total 16 but can be // reduced to 8 transformations after eliminating redundancies. // // All matrices represented here are in the form // // | xx xy | // | yx yy | // // And ignore scaling. // // Reflection is applied before rotation gfx::Matrix rotation = layerTransform; // Compute fuzzy zero like PreservesAxisAlignedRectangles() if (fabs(rotation._11) < 1e-6) { if (rotation._21 < 0) { if (rotation._12 > 0) { // 90 degree rotation // // | 0 -1 | // | 1 0 | // hwcLayer.transform = HWC_TRANSFORM_ROT_90; LOGD("Layer rotated 90 degrees"); } else { // Horizontal reflection then 90 degree rotation // // | 0 -1 | | -1 0 | = | 0 -1 | // | 1 0 | | 0 1 | | -1 0 | // // same as vertical reflection then 270 degree rotation // // | 0 1 | | 1 0 | = | 0 -1 | // | -1 0 | | 0 -1 | | -1 0 | // hwcLayer.transform = HWC_TRANSFORM_ROT_90 | HWC_TRANSFORM_FLIP_H; LOGD("Layer vertically reflected then rotated 270 degrees"); } } else { if (rotation._12 < 0) { // 270 degree rotation // // | 0 1 | // | -1 0 | // hwcLayer.transform = HWC_TRANSFORM_ROT_270; LOGD("Layer rotated 270 degrees"); } else { // Vertical reflection then 90 degree rotation // // | 0 1 | | -1 0 | = | 0 1 | // | -1 0 | | 0 1 | | 1 0 | // // Same as horizontal reflection then 270 degree rotation // // | 0 -1 | | 1 0 | = | 0 1 | // | 1 0 | | 0 -1 | | 1 0 | // hwcLayer.transform = HWC_TRANSFORM_ROT_90 | HWC_TRANSFORM_FLIP_V; LOGD("Layer horizontally reflected then rotated 270 degrees"); } } } else if (rotation._11 < 0) { if (rotation._22 > 0) { // Horizontal reflection // // | -1 0 | // | 0 1 | // hwcLayer.transform = HWC_TRANSFORM_FLIP_H; LOGD("Layer rotated 180 degrees"); } else { // 180 degree rotation // // | -1 0 | // | 0 -1 | // // Same as horizontal and vertical reflection // // | -1 0 | | 1 0 | = | -1 0 | // | 0 1 | | 0 -1 | | 0 -1 | // hwcLayer.transform = HWC_TRANSFORM_ROT_180; LOGD("Layer rotated 180 degrees"); } } else { if (rotation._22 < 0) { // Vertical reflection // // | 1 0 | // | 0 -1 | // hwcLayer.transform = HWC_TRANSFORM_FLIP_V; LOGD("Layer rotated 180 degrees"); } else { // No rotation or reflection // // | 1 0 | // | 0 1 | // hwcLayer.transform = 0; } } const bool needsYFlip = state.OriginBottomLeft() ? true : false; if (needsYFlip) { // Invert vertical reflection flag if it was already set hwcLayer.transform ^= HWC_TRANSFORM_FLIP_V; } hwc_region_t region; if (visibleRegion.GetNumRects() > 1) { mVisibleRegions.push_back(HwcUtils::RectVector()); HwcUtils::RectVector* visibleRects = &(mVisibleRegions.back()); bool isVisible = false; if(!HwcUtils::PrepareVisibleRegion(visibleRegion, layerTransform, layerBufferTransform, clip, bufferRect, visibleRects, isVisible)) { LOGD("A region of layer is too small to be rendered by HWC"); return false; } if (!isVisible) { // Layer is not visible, no need to render it return true; } region.numRects = visibleRects->size(); region.rects = &((*visibleRects)[0]); } else { region.numRects = 1; region.rects = &(hwcLayer.displayFrame); } hwcLayer.visibleRegionScreen = region; } else { hwcLayer.flags |= HwcUtils::HWC_COLOR_FILL; ColorLayer* colorLayer = aLayer->AsColorLayer(); if (colorLayer->GetColor().a < 1.0) { LOGD("Color layer has semitransparency which is unsupported"); return false; } hwcLayer.transform = colorLayer->GetColor().ToABGR(); } mHwcLayerMap.AppendElement(static_cast(aLayer->ImplData())); mList->numHwLayers++; return true; } #if ANDROID_VERSION >= 17 bool HwcComposer2D::TryHwComposition(nsScreenGonk* aScreen) { DisplaySurface* dispSurface = aScreen->GetDisplaySurface(); if (!(dispSurface && dispSurface->lastHandle)) { LOGD("H/W Composition failed. DispSurface not initialized."); return false; } // Add FB layer int idx = mList->numHwLayers++; if (idx >= mMaxLayerCount) { if (!ReallocLayerList() || idx >= mMaxLayerCount) { LOGE("TryHwComposition failed! Could not add FB layer"); return false; } } Prepare(dispSurface->lastHandle, -1, aScreen); /* Possible composition paths, after hwc prepare: 1. GPU Composition 2. BLIT Composition 3. Full OVERLAY Composition 4. Partial OVERLAY Composition (GPU + OVERLAY) */ bool gpuComposite = false; bool blitComposite = false; bool overlayComposite = true; for (int j=0; j < idx; j++) { if (mList->hwLayers[j].compositionType == HWC_FRAMEBUFFER || mList->hwLayers[j].compositionType == HWC_BLIT) { // Full OVERLAY composition is not possible on this frame // It is either GPU / BLIT / partial OVERLAY composition. overlayComposite = false; break; } } if (!overlayComposite) { for (int k=0; k < idx; k++) { switch (mList->hwLayers[k].compositionType) { case HWC_FRAMEBUFFER: gpuComposite = true; break; case HWC_BLIT: blitComposite = true; break; case HWC_OVERLAY: { // HWC will compose HWC_OVERLAY layers in partial // Overlay Composition, set layer composition flag // on mapped LayerComposite to skip GPU composition mHwcLayerMap[k]->SetLayerComposited(true); uint8_t opacity = std::min(0xFF, (int)(mHwcLayerMap[k]->GetLayer()->GetEffectiveOpacity() * 256.0)); if ((mList->hwLayers[k].hints & HWC_HINT_CLEAR_FB) && (opacity == 0xFF)) { // Clear visible rect on FB with transparent pixels. hwc_rect_t r = mList->hwLayers[k].displayFrame; mHwcLayerMap[k]->SetClearRect(nsIntRect(r.left, r.top, r.right - r.left, r.bottom - r.top)); } break; } default: break; } } if (gpuComposite) { // GPU or partial OVERLAY Composition return false; } else if (blitComposite) { // BLIT Composition, flip DispSurface target GetGonkDisplay()->UpdateDispSurface(aScreen->GetEGLDisplay(), aScreen->GetEGLSurface()); DisplaySurface* dispSurface = aScreen->GetDisplaySurface(); if (!dispSurface) { LOGE("H/W Composition failed. NULL DispSurface."); return false; } mList->hwLayers[idx].handle = dispSurface->lastHandle; mList->hwLayers[idx].acquireFenceFd = dispSurface->GetPrevDispAcquireFd(); } } // BLIT or full OVERLAY Composition return Commit(aScreen); } bool HwcComposer2D::Render(nsIWidget* aWidget) { nsScreenGonk* screen = static_cast(aWidget)->GetScreen(); // HWC module does not exist or mList is not created yet. if (!mHal->HasHwc() || !mList) { return GetGonkDisplay()->SwapBuffers(screen->GetEGLDisplay(), screen->GetEGLSurface()); } else if (!mList && !ReallocLayerList()) { LOGE("Cannot realloc layer list"); return false; } DisplaySurface* dispSurface = screen->GetDisplaySurface(); if (!dispSurface) { LOGE("H/W Composition failed. DispSurface not initialized."); return false; } if (mPrepared) { // No mHwc prepare, if already prepared in current draw cycle mList->hwLayers[mList->numHwLayers - 1].handle = dispSurface->lastHandle; mList->hwLayers[mList->numHwLayers - 1].acquireFenceFd = dispSurface->GetPrevDispAcquireFd(); } else { // Update screen rect to handle a case that TryRenderWithHwc() is not called. mScreenRect = screen->GetNaturalBounds().ToUnknownRect(); mList->flags = HWC_GEOMETRY_CHANGED; mList->numHwLayers = 2; mList->hwLayers[0].hints = 0; mList->hwLayers[0].compositionType = HWC_FRAMEBUFFER; mList->hwLayers[0].flags = HWC_SKIP_LAYER; mList->hwLayers[0].backgroundColor = {0}; mList->hwLayers[0].acquireFenceFd = -1; mList->hwLayers[0].releaseFenceFd = -1; mList->hwLayers[0].displayFrame = {0, 0, mScreenRect.width, mScreenRect.height}; Prepare(dispSurface->lastHandle, dispSurface->GetPrevDispAcquireFd(), screen); } // GPU or partial HWC Composition return Commit(screen); } void HwcComposer2D::Prepare(buffer_handle_t dispHandle, int fence, nsScreenGonk* screen) { if (mPrepared) { LOGE("Multiple hwc prepare calls!"); } hwc_rect_t dispRect = {0, 0, mScreenRect.width, mScreenRect.height}; mHal->Prepare(mList, screen->GetDisplayType(), dispRect, dispHandle, fence); mPrepared = true; } bool HwcComposer2D::Commit(nsScreenGonk* aScreen) { for (uint32_t j=0; j < (mList->numHwLayers - 1); j++) { mList->hwLayers[j].acquireFenceFd = -1; if (mHwcLayerMap.IsEmpty() || (mList->hwLayers[j].compositionType == HWC_FRAMEBUFFER)) { continue; } LayerRenderState state = mHwcLayerMap[j]->GetLayer()->GetRenderState(); if (!state.mTexture) { continue; } FenceHandle fence = state.mTexture->GetAndResetAcquireFenceHandle(); if (fence.IsValid()) { RefPtr fdObj = fence.GetAndResetFdObj(); mList->hwLayers[j].acquireFenceFd = fdObj->GetAndResetFd(); } } int err = mHal->Set(mList, aScreen->GetDisplayType()); mPrevRetireFence.TransferToAnotherFenceHandle(mPrevDisplayFence); for (uint32_t j=0; j < (mList->numHwLayers - 1); j++) { if (mList->hwLayers[j].releaseFenceFd >= 0) { int fd = mList->hwLayers[j].releaseFenceFd; mList->hwLayers[j].releaseFenceFd = -1; RefPtr fdObj = new FenceHandle::FdObj(fd); FenceHandle fence(fdObj); LayerRenderState state = mHwcLayerMap[j]->GetLayer()->GetRenderState(); if (!state.mTexture) { continue; } state.mTexture->SetReleaseFenceHandle(fence); } } if (mList->retireFenceFd >= 0) { mPrevRetireFence = FenceHandle(new FenceHandle::FdObj(mList->retireFenceFd)); } // Set DisplaySurface layer fence DisplaySurface* displaySurface = aScreen->GetDisplaySurface(); displaySurface->setReleaseFenceFd(mList->hwLayers[mList->numHwLayers - 1].releaseFenceFd); mList->hwLayers[mList->numHwLayers - 1].releaseFenceFd = -1; mPrepared = false; return !err; } #else bool HwcComposer2D::TryHwComposition(nsScreenGonk* aScreen) { mHal->SetEGLInfo(aScreen->GetEGLDisplay(), aScreen->GetEGLSurface()); return !mHal->Set(mList, aScreen->GetDisplayType()); } bool HwcComposer2D::Render(nsIWidget* aWidget) { nsScreenGonk* screen = static_cast(aWidget)->GetScreen(); return GetGonkDisplay()->SwapBuffers(screen->GetEGLDisplay(), screen->GetEGLSurface()); } #endif bool HwcComposer2D::TryRenderWithHwc(Layer* aRoot, nsIWidget* aWidget, bool aGeometryChanged) { if (!mHal->HasHwc()) { return false; } nsScreenGonk* screen = static_cast(aWidget)->GetScreen(); if (mList) { mList->flags = mHal->GetGeometryChangedFlag(aGeometryChanged); mList->numHwLayers = 0; mHwcLayerMap.Clear(); } if (mPrepared) { mHal->ResetHwc(); mPrepared = false; } // XXX: The clear() below means all rect vectors will be have to be // reallocated. We may want to avoid this if possible mVisibleRegions.clear(); mScreenRect = screen->GetNaturalBounds().ToUnknownRect(); MOZ_ASSERT(mHwcLayerMap.IsEmpty()); if (!PrepareLayerList(aRoot, mScreenRect, gfx::Matrix())) { mHwcLayerMap.Clear(); LOGD("Render aborted. Nothing was drawn to the screen"); return false; } // Send data to LayerScope for debugging SendtoLayerScope(); if (!TryHwComposition(screen)) { LOGD("Full HWC Composition failed. Fallback to GPU Composition or partial OVERLAY Composition"); LayerScope::CleanLayer(); return false; } LOGD("Frame rendered"); return true; } void HwcComposer2D::SendtoLayerScope() { if (!LayerScope::CheckSendable()) { return; } const int len = mList->numHwLayers; for (int i = 0; i < len; ++i) { LayerComposite* layer = mHwcLayerMap[i]; const hwc_rect_t r = mList->hwLayers[i].displayFrame; LayerScope::SendLayer(layer, r.right - r.left, r.bottom - r.top); } } } // namespace mozilla